2021
DOI: 10.1021/acs.chemmater.1c01983
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Design Principles for Multinary Metal Chalcogenides: Toward Programmable Reactivity in Energy Conversion

Abstract: Transformative solutions to contemporary energy problems hinge on the successful development of non-noble functional materials. A promising avenue toward sustainable energy conversion and storage is the synthesis and integration of electrocatalyst materials with interfaces that drive small-molecule electroreduction reactions like CO2 and CO conversion to fuels, as well as hydrogen production from water. While research advances in the past several decades have led to deployable technologies on both of these fro… Show more

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Cited by 17 publications
(12 citation statements)
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“…We note that these proposed NRR screening criteria differ from the previously suggested NRR scaling relations of N 2 → *NNH vs *NH 2 → NH 3 . The multinary Chevrel phases may provide an ideal platform for designing superior NRR electrocatalysts due to the similarity of their active sites to the nitrogenase cofactors and their tunable compositions that allow a range of chalcogenide stoichiometries and transition-metal intercalants. Expanding the set of NRR electrocatalysts that break scaling relations via GC-DFT studies may elucidate the importance of narrow bands of surface d -states near −6.5 eV below the Fermi level, concomitant N 2 adsorption and subsurface bond dissociation, and the trigonal pyramidal active site geometry (tetrahedral with *N x H y ).…”
Section: Resultsmentioning
confidence: 92%
“…We note that these proposed NRR screening criteria differ from the previously suggested NRR scaling relations of N 2 → *NNH vs *NH 2 → NH 3 . The multinary Chevrel phases may provide an ideal platform for designing superior NRR electrocatalysts due to the similarity of their active sites to the nitrogenase cofactors and their tunable compositions that allow a range of chalcogenide stoichiometries and transition-metal intercalants. Expanding the set of NRR electrocatalysts that break scaling relations via GC-DFT studies may elucidate the importance of narrow bands of surface d -states near −6.5 eV below the Fermi level, concomitant N 2 adsorption and subsurface bond dissociation, and the trigonal pyramidal active site geometry (tetrahedral with *N x H y ).…”
Section: Resultsmentioning
confidence: 92%
“…The design of multinary nanocrystals was aimed at improving the catalytic activity and stability of binary transition metal chalcogenides. [138][139][140][141][142] A multinary transition metal compound is composed of at least two different metals. The formation of multinary transition metal chalcogenide introduces some unique properties different from those of binary compounds while retaining inherent properties.…”
Section: Photo-electrochemical (Pec) Water Splittingmentioning
confidence: 99%
“…Photocatalytic reduction of both CO 2 and H + are thus thermodynamically favorable. To promote the selective reduction of CO 2 may require doping the QDs or interfacing QDs with CO 2 -reduction cocatalysts, potentially including MoS 2 or other transition metal chalcogenides. Recent reports have highlighted the potential to control products of photocatalytic reduction of CO 2 or H + with the size of QDs. , Products of CO 2 reduction at M x V 2 O 5 /QD and M x M y ′ V 2 O 5 /QD heterostructures may thus depend on the energy of electrons in QDs. A range of II–VI and III–V QDs, readily interfaced with M x V 2 O 5 or M x M y ′ V 2 O 5 surfaces via SILAR or LAA, have bulk E c values within and more negative than relevant CO 2 -reduction potentials (Figure B).…”
Section: Prospects For Photocatalysis Beyond Hydrogen Evolutionmentioning
confidence: 99%